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Confining T-joints by adding two outer hollow ring flanges
welded to additional hollow circular pipe
Journal: Canadian Journal of Civil Engineering
Manuscript ID cjce-2017-0065.R1
Manuscript Type: Article
Date Submitted by the Author: 11-May-2017
Complete List of Authors: Melek, Peter; Dar Al-Handasah Consultants, Structures Department AbdelGhani, Mohamed; Dar Al-Handasah Consultants, Structures Department Gaawan, Sameh; Helwan University, Faculty of engineering Mataria branch, Structures Department
Is the invited manuscript for
consideration in a Special Issue? :
N/A
Keyword: CHS, T-joint, Strengthening, stiffening, outer hollow ring
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Confining T-joints by adding two outer hollow ring flanges welded to 1 additional hollow circular pipe 2
Peter Gerges1,a, Mohamed Hussein1,b, Sameh Gaawan 2,c 3 1Structural Engineer, Dar Al-Handasah Consultants, Structures Department, Street 26 Building 10 - Smart Village, Giza 12577 , Egypt 4 2Associate Professor, Helwan University, Faculty of engineering Mataria branch, Structures Department, Ibrahim Abdel Razeq Street, Cairo 11718, Egypt 5
ABSTRACT 6
Increasing the capacity of CHS T-joints is a challenge for the designers due to its closed nature which makes 7 strengthening difficult as the traditional strengthening techniques focus on adding ring stiffeners inside the chord, 8 these techniques require splitting the chord at each joint location into more than one part and this is not applicable for 9 stiffening prefabricated and erected T-joints. This paper presents a proposed strengthening technique depends on 10 confining the T-joint by two outer hollow ring flanges welded to additional hollow circular pipe. A parametric study 11 is carried out to investigate the effect of the hollow ring flanges diameter, the added elements thickness, and the 12 spacing between the hollow outer ring flanges on increasing the capacity of T-joints for different values of β (db/d0: 13 brace diameter-to-chord diameter ratio) when the brace is either subjected to tension or compression force. Finally, it 14 is observed that the compressive T-joints gain up to 267% of its original capacity and the tensile T-joints gain up to 15 65% of its original capacity. 16
Key words: CHS, T-joint, Strengthening, stiffening, outer hollow ring. 17 18
1. INTRODUCTION 19
Welded circular hollow steel sections are commonly used in different kind of structures as they are required 20 architecturally for their pleasing appearance, and they are also recommended structurally because of their reduced 21 weight and surface area when compared to equivalent open steel profiles. The adequacy of the connection of CHS is 22 an integral part of the CHS design, so it is important for engineer to be aware of different strengthening/stiffening 23 techniques to choose the most suitable for the case. Strengthening and stiffening techniques can be classified into two 24 types: 25
I) Techniques in which stiffening elements are added inside the chord. 26 II) Techniques in which stiffening elements are added on the outer surface of the chord. 27
Here is a brief literature review on some of different strengthening techniques for CHS T-joints that have been 28 previously studied to increase the capacity of the joints: 29 For the first type of strengthening techniques, Lee and Llewelyn-Parry (2004) studied CHS T-joints strengthening 30 by adding internal ring stiffeners to increase the strength of the joint and they also investigate the effect of β, γ (d0/t0: 31 chord diameter–to-chord thickness), depth of the internal ring, thickness of the internal ring and the number of internal 32 ring. Shao, Lie and Chiew (2010) stiffened the CHS T-joints subjected to axial compressive brace by thickening the 33 chord near the brace-chord intersection and they clarified the effect of β, γ, and the thickness of reinforced chord to 34 the thickness of unreinforced chord ratio. Welding an inner doubler plate to the internal surface of the chord at the 35 brace-chord intersection is a technique that was studied by Shubin, Yongbo and Hongyan (2013). 36 37 38 39 a [email protected], b [email protected], c [email protected] 40 41 Corresponding author: 42 Peter Gerges1,a , Structural Engineer, Dar Al-Handasah Consultants, Structures Department, Street 26 Building 10 - Smart 43 Village, Giza 12577 , Egypt. 44 E-mail: [email protected] 45 Tel: +202 3531 8000 46 47
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For the second type of strengthening techniques, Lesani, Bahaari, and Shokrieh (2013) enhanced the capacity of the 48 CHS T- joint subjected to axial brace compressive loading by adding fiber reinforced polymer. Zhu, Zhao, Li, Huang, 49 and Ban in (2014) reinforced CHS T-joints by external stiffener and studied the effect of the length and the height of 50 the stiffener. Zhu, Han, Song, Ma, Wei and Li (2016) carried out an experimental study to investigate the effect of 51 adding external stiffening rings on improving the CHS T-joints axial compressive strength. Another technique using 52 through bolts in the chord at the brace location was carried out by Mohamed, Shaat, and Sayed-Ahmed (2013) in 53 this technique the gain in the joint strength reached 41%. 54
The disadvantage of strengthening technique type (I) is the impossibility of using it with erected CHS T-joints as it 55 requires splitting the chord into more than one part to be able to add the stiffening elements inside the chord which is 56 very difficult for execution. While the disadvantage of strengthening technique type (II) is either the CHS T-Joint 57 doesn’t gain much increasing in the capacity if small stiffeners are used, or the aesthetic appearance will be lost with 58 using large stiffeners. Using outer collars of FRP is one of strengthening techniques type (II), but the low fire resistance 59 of FRB is limiting the using of this method. 60
However, Choo, Vegte, Zettlemoyer, and Liew (2005) avoided the disadvantages mentioned above by reinforcing 61 the T-joints by doubler plates or collar plates either under tensile or compression loading. The study provided the 62 experimental results for four unreinforced specimens and also the experimental results of eight reinforced specimens. 63 The study was extended to simulate the reinforced and unreinforced T-joints by numerical simulations which were 64 well correlated with the experimental results. Choo, Liang, and van der Vegte (2004) continued on studying the 65 effect of a collar plate by investigating the effect of collar plates on the capacity X-joints reinforced with a collar plate 66 under different types of loading (axially compressive, in-plane bending and out of plane bending. Also Nassiraei, 67 Lotfollahi-Yaghin, and Ahmadi (2016) extended the research on studying the effect of collar plate on reinforced 68 tubular T/Y joints subjected to compressive brace by carrying out a parametric study to investigate the effect of plate 69 size and joint geometry on the joint capacity, also a new equation based on nonlinear regression analysis was proposed 70 to determine the ultimate compressive strength of reinforced T/Y joints. 71
In this study, proposed strengthening technique depends on confining the brace-chord intersection by using two outer 72 hollow ring flanges -with diameter not much bigger than that of the chord so as not to lose the aesthetic appearance- 73 in addition to welding a hollow circular pipe to these ring flanges (illustrated in Fig.1). Therefore, this new technique 74 overcomes the disadvantage of strengthening types (I), (II) previously mentioned as it is applicable with prefabricated 75 or erected CHS T-Joints with gaining up to 267% of its original compressive capacity and up to 65% of its original 76 tensile capacity, without losing the circular aesthetic appearance of the circular hollow steel section. The behavior of 77 this technique is studied in this paper numerically by performing 112 finite element models. 78 79 80
81 82
Fig.1. Confining T-joints by adding two outer hollow ring flanges welded to additional hollow circular pipe 83
84
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From practical point of view, the fabrication of the proposed strengthening technique can be carried out by applying 85 the following procedures which are clarified in (Fig.2): 86
Step 1 Fabricating the strengthening components in two equal parts. Each part consists of half circular 87 pipe welded to two halves of ring flanges. 88 Step 2 Welding the additional hollow circular pipe (part 1) to the branch of the original unstiffened T-89 joint, and then welding the two outer hollow ring flanges (part 1) to the chord of the original unstiffened T-90 joint. 91 Step 3 Welding the additional hollow circular pipe (part 2) to the branch of the original unstiffened T-92 joint, and then welding the two outer hollow ring flanges (part 2) to the chord of the original unstiffened T-93 joint. 94 Step 4 Welding stiffening components of part (1) with that of part (2). 95
Fig.2. Fabrication procedure 96
97
2. FINITE ELEMENT MODELING 98
The first step taken in this study is to make sure that the finite element models are accurate and reliable for the 99 parametric study and that is done by calibrating seven models with independent unreinforced specimens that have 100 been tested experimentally, four of them were tested by Choo et al. (2005) and the other three were tested by Zhu 101 et al. (2014). Table 1 shows Specimen ID (as per the reference), the CHS dimensions used in the tests. 102
103
104
105
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Table 1. Specimens experimentally tested by Choo et al. (2005) and Zhu et al. (2014). 106
Reference Specimen ID
Loading type
do (mm)
to (mm)
lo (mm)
db (mm)
tb (mm)
lb (mm)
Choo et
al. (2005)
EX-01 Compression 409.5 8.1 2840 221.9 6.8 1100 EX-02 Tension 409.5 8.1 2840 221.9 6.8 1100 EX-09 Compression 409.5 8.5 2840 114.7 5.9 1100 EX-10 Tension 409.5 8.5 2840 114.7 5.9 1100
Zhu et al. (2014)
T1 Compression 298 5.6 1800 76.3 6.2 375 T3 Compression 298.1 5.8 1800 147.2 6.4 745 T5 Compression 297.9 6.1 1800 220.2 6.5 1126.5
107 a. ELEMENT TYPE AND MESHING 108
In this paper the numerical study is carried out by modeling 112 finite element models using software ANSYS 14. The 109 steel elements in these models are simulated by using four node strain shell element “Shell 181” that is included in 110 ANSYS elements library as the properties of this type of element is convenient for such simulation. Here is a brief 111 description for the used shell element type: SHELL181 “is suitable for analyzing thin to moderately-thick shell 112 structures. It is a four-node element with six degrees of freedom at each node: translations in the x, y, and z directions, 113 and rotations about the x, y, and z-axes. SHELL181 is well-suited for linear, large rotation, and/or large strain 114 nonlinear applications”. (Fig.3) shows the geometry, node locations, and the element coordinate system for this 115 element. 116
As for the meshes size it was found that using size of 25 mm gives accurate 117 realistic results when compared with that obtained from laboratory tests (this 118 is shown below in section (2.d). Therefore, meshes of size 25 are used for all 119 the elements in the numerical models in this paper. 120
121
122
123
Fig.3. Shell 181 used in FEM 124
b. MATERIAL MECHANICAL PROPERTIES 125
To represent the material mechanical properties in the finite element modeling, a bilinear isotropic hardening elastic 126 perfectly plastic material is used. The material properties of the chord and brace of each model follows the same ones 127 that used for the unreinforced specimens tested by Choo et al. (2005) and by Zhu et al. (2014). Table 2 shows 128 mechanical properties used in the tests for each specimen; where E0 is the Young’s modulus of the chords, Eb is the 129 Young’s modulus of the braces, fy,0 is the yield stress for chords, and fy,b is the yield stress for braces. For the additional 130 strengthening elements; the mechanical properties of the chord are followed. 131
Table 2. Mechanical properties of the specimens used for FEM calibration 132
Specimen ID
Eo (KN/mm2)
Eb (KN/mm2)
fy,0
(N/mm2) fy,b
(N/mm2) EX-01 200 200 285 300 EX-02 200 200 285 300 EX-09 200 200 276 312 EX-10 200 200 276 312
T1 227 224 345 470 T3 227 224 345 368 T5 227 183 345 352
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133
c. WELD MODELING 134
In this study, the weld is considered to be complete joint penetration following the mechanical properties of the 135 chord, while the weld thickness is following the thickness of connected steel elements. 136
137
d. LOADING AND BOUNDARY CONDITIONS 138
The brace load either compressive or tensile axial load is applied on thick ring plate which is placed on the brace end. 139 The brace axial load is simulated by pressure or suction on the thick plate in order to ensure the uniformity of the load 140 distribution. 141
For the calibration models of specimens ID (EX-01, EX-02, EX-09, and EX-10). The chord’s two ends for a length 142 of 150 mm was supported vertically (Y direction) and laterally (Z direction), but unrestrained longitudinally (X 143 direction). For the brace end, it is supported horizontally in X, Z directions to follow the test arrangements mentioned 144 by Choo et al. (2005). At the location of supports of the chord, thick vertical plates are added to match the test 145 arrangement and to avoid the local 146 failures at the supports. For the 147 calibration models of specimens ID 148 (T1, T3, T5) the chord’s two ends 149 were closed by a thick vertical 150 plate. One end supported vertically, 151 longitudinally and horizontally, 152 while the other end supported 153 vertically and horizontally. Note 154 that these boundary conditions was 155 only used for calibration the 156 models of specimens ID (T1, T3, 157 T5). The boundary conditions of 158 specimens ID (EX-01, EX-02, EX-159 09, and EX-10) shown in Fig.4 are 160 followed in all finite element 161 models used for the parametric 162 study. 163
Fig.4. FEM statical system used for the parametric study 164
165
e. FINITE ELEMENT MODELS VERIFICATION 166
Based on the element type, meshes size, material mechanical properties, loading and boundary conditions mentioned 167 above in sections (2.a), (2.b) and (2.c) respectively the numerical results for seven models are obtained as shown in 168 Table 3. 169
170
171
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Table 3. Experimental results compared to numerical results. 172
Specimen ID
Experimental Nominal strength Ptest (KN)
Numerical Nominal strength Pnum. (KN)
Pexp./Pnum NOMINAL STRENGTH TYPE
error %
EX-01 -305.1 -305.4 1 peak load 0.1% EX-02 +543.2 +567.3 0.96 ovalisation 4.2% EX-09 -200.1 -176.2 1.14 peak load 13.6% EX-10 +407.8 +413 0.99 ovalisation 1.30%
T1 -85 -87.8 0.97 peak load 3.2% T3 -155 -163.3 0.95 peak load 5.1% T5 -249.7 -276.2 0.90 peak load 9.6%
Average error % 5.3% Notes:
• (+) sign denotes tensile load, (-) sign denotes compression load. • Nominal strength is the minimum of peak load of the joint or the load opposite to
ovalisation of 0.06do as mentioned by Choo et al. (2005).
The numerical results shown in Table 3 are well correlated with the experimental results with acceptable errors. 173 Therefore, the finite element modeling as explained is trustable to be used in the parametric study. Another 174 deformation limit criteria had been proposed by (Lu et al., 1994) which stated that the ultimate deformation limit 175 occurs when the chord deformation reaches 0.03d0 indentation. Whether following the deformation limit criteria 176 recommended by Choo et al. (2005) or (Lu et al., 1994), the nominal strength type mentioned in table 3 doesn’t 177 change. However, in determining the numerical nominal strength stated in table 3, Choo et al. (2005) deformation 178 limit criteria was followed in order to be consistent with the experimental results obtained by Choo et al. (2005) 179 which are already used in the finite element models verification in the current study. 180
181 Fig.5. Experimental and numerical load-ovalisation curves 182
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Fig. 5 represents the load-ovalisation curves for the calibrated finite element models against the experimental results 183 provided by Choo et al. (2005) and Zhu et al. (2014). It is important to mention that for specimens (EX-01, EX-09, 184 T1, T3 and T5) which are subjected to compression load, the load-ovalisation curves are plotted until the load 185 reached the peak load as the behavior of the joints beyond the peak load isn’t a part of the current study. While as 186 for specimens (EX-02 and EX-04) which are subjected to tensile load, the ultimate load isn’t the peak load, but it is 187 the load corresponding to the deformation limit 0.06do as mentioned by Choo et al. (2005). This deformation limit is 188 plotted as dashed line in Fig. 5 (b, d). Thus, it is concluded from Fig. 5 that there is good agreement between the 189 behavior of the calibrated finite element models and that of the tests carried out by Choo et al. (2005) and Zhu et al. 190 (2014). 191
192
3. PARAMETRIC STUDY 193
A parametric study is performed on CHS T-joints strengthened by the proposed technique (confining the brace-chord 194 intersection by adding two outer hollow ring flanges welded to additional hollow circular pipe) to investigate the gain 195 in the joint strength when compression or tension load is applied on the brace. This parametric study was done by 196 applying the same finite element modeling aspects that were used in the calibration models (i.e. element type, meshing, 197 material and loading). The parametric study has been carried out by performing 104 finite element models based on 198 the calibration models. Half of the models are subjected to compressive brace (category I) and the other subjected 199 tensile brace (category II), each category composed of four groups (A, B, C, D), and each group consists of fourteen 200 models. In each group the chord and brace geometric/material parameters are fixed. In all groups the chord diameter-201 to-double of the chord thickness ratio (2γ = do/to) is almost constant; while the brace diameter-to-chord diameter ratio 202 (β=db/do) varies from group to another. Tables 4 shows the brace-chord profiles, γ and β, used in each group for 203 category (I), (II) respectively. The brace-chord profiles dimensions were chosen in order to follow the unreinforced 204 specimens that have been tested experimentally by Choo et al. (2005) and Zhu et al. (2014). As these specimens have 205 covered a wide range of the brace diameter-to-chord diameter ratio (β=db/do) with almost constant values of chord 206 diameter-to-double the chord thickness ratio (2γ = do/to). 207
In each group: 208
- The radial flange diameter-to-chord diameter (ds/ do) has five values that varies from 1.1 to 1.5. 209 - The stiffening elements thickness-to-chord thickness ratio (ts/to) has five values varies from 0.75 to 1.75. 210 - The additional pipe length-to-brace length ratio (ls/ db) five values that vary from 1.1 to 3. 211
TABLE 4. Chord-brace profiles’ dimensions used in the numerical study. 212
do to db tbI-A 409.5 8.1 221.9 6.8 25.28 0.54I-B 409.5 8.5 114.7 5.9 24.09 0.28I-C 298.1 5.8 147.2 6.4 25.70 0.49I-D 297.9 6.1 220.2 6.5 24.42 0.74II-A 409.5 8.1 221.9 6.8 25.28 0.54II-B 409.5 8.5 114.7 5.9 24.09 0.28II-C 298.1 5.8 147.2 6.4 25.70 0.49II-D 297.9 6.1 220.2 6.5 24.42 0.74
CATEGORY
I
II
GROUPCHORD DIMENSIONS BRANCH DIMENSION
ɣ β
213 All dimensions are in mm. 214
215
4. FINITE ELEMENT MODELS RESULTS 216
Six of the above mentioned calibration models were used to be part of parametric study models, four of these 217 six models -with ID (EX-01, EX-02, EX-09, and EX-10)- were used to be the unreinforced models that will be 218
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strengthened by the new technique in the numerical study, so the results of models I-A-01, I-B-01, II-A-01, II-219 B-01 in tables (5, 6) are the same as the results of relevant calibration models -mentioned in table 2-. While for 220 the calibration models -with ID (T3, T5) - some modifications were applied on the calibration models to unify 221 the parameters to be similar to that of other specimens-with ID (EX-01, EX-02, EX-09, and EX-10)-. This is the 222 cause of the slight difference between the results of models I-C-01, I-D-01 and the results of calibration models 223 of specimen T3, T5.* 224
*[These modifications are applied on the chord span, the brace length, and the boundary conditions so as to be similar to that of specimens 225 with ID (EX-01, EX-02, EX-09, and EX-10).] 226
In each group the model with ID 01, the T-joint is unreinforced. For models with ID (02 to 06), the strengthened T-227 joint is studied to investigate the effect of (ds/do). For models with ID (07 to 10), the strengthened T-joint is studied 228 with different values of (ts/to). The effect of (ls / db) is studied in models with ID (11 to 14). 229
Tables 5, 6 shows the parameters values, the non-dimensional parameters values, the joint capacity, and the gain 230 percentage in each model for category (I), (II) respectively. The results of finite elements models for category (I), 231 (II) are also summarized in Fig.6, Fig.7 respectively. The gain in joint capacity is calculated as shown in equation 232 Eq.1. 233
𝐺𝐺𝐺𝐺𝐺𝐺𝐺𝐺 % = 𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠ℎ 𝑜𝑜𝑜𝑜 𝑠𝑠𝑠𝑠𝑠𝑠𝑜𝑜𝑜𝑜𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠 𝑗𝑗𝑜𝑜𝑠𝑠𝑠𝑠𝑠𝑠−𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠ℎ𝑠𝑠 𝑜𝑜𝑜𝑜 𝑢𝑢𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑜𝑜𝑜𝑜𝑠𝑠𝑢𝑢𝑠𝑠𝑠𝑠 𝑗𝑗𝑜𝑜𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠ℎ𝑠𝑠 𝑜𝑜𝑜𝑜 𝑢𝑢𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑠𝑜𝑜𝑜𝑜𝑠𝑠𝑢𝑢𝑠𝑠𝑠𝑠 𝑗𝑗𝑜𝑜𝑠𝑠𝑠𝑠𝑠𝑠
× 100 Eq. 1 234
235 Fig.6. Summary for the numerical results of category (I) 236
237 Fig.7. Summary for the numerical results of category (II) 238
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Table 5. The FEM results after using the new stiffening technique with category I. 239
ds ts ls ds/do ts/to ls/dbI-A-01 0 0 0 0.00 0.00 0.00 305.4 0.0%I-A-02 450.45 1.10 582 90.6%I-A-03 491.4 1.20 687 125.0%I-A-04 532.35 1.30 781 155.7%I-A-05 573.3 1.40 840 175.0%I-A-06 614.25 1.50 868 184.2%I-A-07 6.075 0.75 511 67.3%I-A-08 10.125 1.25 644 110.9%I-A-09 12.15 1.50 694 127.2%I-A-10 14.175 1.75 739 142.0%I-A-11 332.85 1.50 585 91.6%I-A-12 443.8 2.00 589 92.9%I-A-13 554.75 2.50 602 97.1%I-A-14 665.7 3.00 593 94.2%I-B-01 0 0 0 0.00 0.00 0.00 176.2 0.0%I-B-02 450.45 1.10 399.5 126.7%I-B-03 491.4 1.20 504 186.0%I-B-04 532.35 1.30 595.5 238.0%I-B-05 573.3 1.40 625 254.7%I-B-06 614.25 1.50 625 254.7%I-B-07 6.375 0.75 346 96.4%I-B-08 10.625 1.25 445.5 152.8%I-B-09 12.75 1.50 486 175.8%I-B-10 14.875 1.75 520 195.1%I-B-11 172.05 1.50 400 127.0%I-B-12 229.4 2.00 382 116.8%I-B-13 286.75 2.50 372.5 111.4%I-B-14 344.1 3.00 368 108.9%I-C-01 0 0 0 0.00 0.00 0.00 176 0.0%I-C-02 327.9 1.10 347 97.2%I-C-03 357.7 1.20 400.2 127.4%I-C-04 387.5 1.30 441.8 151.0%I-C-05 417.3 1.40 448.5 154.8%I-C-06 447.1 1.50 449 155.1%I-C-07 4.35 0.75 304.8 73.2%I-C-08 7.25 1.25 385 118.8%I-C-09 8.7 1.50 414 135.2%I-C-10 10.15 1.75 431 144.9%I-C-11 220.8 1.50 343 94.9%I-C-12 294.4 2.00 343 94.9%I-C-13 368 2.50 351 99.4%I-C-14 441.6 3.00 351 99.4%I-D-01 0 0 0 0.00 0.00 0.00 299.9 0.0%I-D-02 327.7 1.10 468.5 56.2%I-D-03 357.5 1.20 480 60.1%I-D-04 387.3 1.30 486 62.1%I-D-05 417 1.40 486 62.1%I-D-06 447 1.50 486 62.1%I-D-07 4.575 0.75 440 46.7%I-D-08 7.625 1.25 483 61.1%I-D-09 9.15 1.50 486 62.1%I-D-10 10.675 1.75 486 62.1%I-D-11 330.3 1.50 482 60.7%I-D-12 440.4 2.00 502 67.4%I-D-13 550.5 2.50 510 70.1%I-D-14 660.6 3.00 510 70.1%
1.10
I-B
I-C
I-A
1.10
1.10
1.00
1.00
1.10
I-D
1.00
1.00
1.10
1.10
1.00
1.00
1.10
450.45
8.5
126
8.5
1.00
1.00
1.10
450.45
8.1
8.1
244
327.9
5.8
5.8
161.92
327.7
6.1
242.22
6.1
GAIN %GROUP MODEL IDADDED PIPE DIMENSIONS (mm) NON-DIMENSIONAL PARAMETERS JOINT CAPACITY (KN)
240 241
242
243
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Table 6. The FEM results after using the new stiffening technique with category II. 244
ds ts ls ds/do ts/to ls/dbII-A-01 0 0 0 0.00 0.00 0.00 567 0.0%II-A-02 450.45 1.10 807.7 42.5%II-A-03 491.4 1.20 826.6 45.8%II-A-04 532.35 1.30 838.8 47.9%II-A-05 573.3 1.40 874 54.1%II-A-06 614.25 1.50 874 54.1%II-A-07 6.075 0.75 774.5 36.6%II-A-08 10.125 1.25 858 51.3%II-A-09 12.15 1.50 889 56.8%II-A-10 14.175 1.75 889 56.8%II-A-11 332.85 1.50 826.8 45.8%II-A-12 443.8 2.00 857.9 51.3%II-A-13 554.75 2.50 913 61.0%II-A-14 665.7 3.00 936 65.1%II-B-01 0 0 0 0.00 0.00 0.00 413 0.0%II-B-02 450.45 1.10 600.6 45.4%II-B-03 491.4 1.20 617.6 49.5%II-B-04 532.35 1.30 618.7 49.8%II-B-05 573.3 1.40 618.7 49.8%II-B-06 614.25 1.50 618.7 49.8%II-B-07 6.375 0.75 560.5 35.7%II-B-08 10.625 1.25 614 48.7%II-B-09 12.75 1.50 614 48.7%II-B-10 14.875 1.75 615 48.9%II-B-11 172.05 1.50 614 48.7%II-B-12 229.4 2.00 614 48.7%II-B-13 286.75 2.50 614 48.7%II-B-14 344.1 3.00 614 48.7%II-C-01 0 0 0 0.00 0.00 0.00 322 0.0%II-C-02 327.9 1.10 453 40.7%II-C-03 357.7 1.20 454.8 41.2%II-C-04 387.5 1.30 454.8 41.2%II-C-05 417.3 1.40 454.8 41.2%II-C-06 447.1 1.50 454.8 41.2%II-C-07 4.35 0.75 450 39.8%II-C-08 7.25 1.25 459 42.5%II-C-09 8.7 1.50 459 42.5%II-C-10 10.15 1.75 459 42.5%II-C-11 220.8 1.50 470.8 46.2%II-C-12 294.4 2.00 486 50.9%II-C-13 368 2.50 502 55.9%II-C-14 441.6 3.00 520 61.5%II-D-01 0 0 0 0.00 0.00 0.00 470 0.0%II-D-02 327.7 1.10 497 5.7%II-D-03 357.5 1.20 495 5.3%II-D-04 387.3 1.30 496 5.5%II-D-05 417 1.40 494 5.1%II-D-06 446.8 1.50 489 4.0%II-D-07 4.575 0.75 496 5.5%II-D-08 7.625 1.25 496 5.5%II-D-09 9.15 1.50 496 5.5%II-D-10 10.675 1.75 495 5.3%II-D-11 330.3 1.50 514 9.4%II-D-12 440.4 2.00 543 15.5%II-D-13 550.5 2.50 570 21.3%II-D-14 660.6 3.00 601 27.9%
GROUP MODEL IDADDED PIPE DIMENSIONS (mm)
II-D
327.9
1.00
450.45
8.1
244
8.1
1.00
1.10
II-A
5.8
5.8
161.92
II-B
II-C
126
8.5
450.45
8.5
1.10
1.10
1.00
GAIN %
1.10
1.00
1.10
1.10
1.00
1.00
1.10
1.00
1.00
1.10
NON-DIMENSIONAL PARAMETERS
327.7
6.1
6.1
242.22
JOINT CAPACITY (KN)
245
246
247
248
249
250
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5. FAILURE MODES AND DEFORMED SHAPES 251 252
This part of the accompanied paper focuses on the joint behavior before and after strengthening by the proposed 253 technique. For each group, the deformed shape and the corresponding stress distribution across the chord/brace at 254 the brace chord intersection for unstiffened joints is compared to that of the stiffened joints to investigate the 255 performance of the new strengthening technique. 256
For groups (I-A, I-B, I-C, I-D and II-A) the joint behavior is compared between the unstiffened models (ID-01) and 257 the models with ID-02 which have smallest radial flange diameter (ds/do=1.1), stiffening elements thickness equals 258 to the chord thickness (ts/to=1) and smallest additional pipe length (ls/db =1.1) in order to investigate the effect of the 259 parameters on strengthened joint. Also to investigate the effect of radial flange diameter parameter (ds) individually, 260 the behavior of models with ID-06 which have the largest radial flange diameter (ds/do=1.5) is compared with the 261 models with ID-02. To study the effect stiffening elements thickness (ts) individually, the behavior of models with 262 ID-10 which have the largest stiffening elements thickness (ts/to=1.75) is compared with the models with ID-02. 263 Similarly to investigate the effect of additional pipe length (ls) separately, the behavior of models with ID-14 which 264 have the largest radial flange diameter (ds/do=1.5) is compared with the models with ID-02. 265
While as for groups (II-B, II-C and II-D), the joint behavior is compared between the unstiffened models (ID-01) 266 and the models with ID-02 which have smallest radial flange diameter (ds/do=1.1), stiffening elements thickness 267 equals to the chord thickness (ts/to=1) and smallest additional pipe length (ls/db =1.1). The behavior of this model 268 (ID-02) is similar to the rest of the models that is why the behavior of the other models (ID 06, 10 and 14) are not 269 shown in figures (18, 20 and 22). 270
a. THE FAILURE MODE AND DEFORMED SHAPE FOR GROUP I-A 271
272 Fig. 8 The behavior of group I-A 273
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274 Fig. 9 Load-ovalisation curves for FEM (I-A-01, I-A-02, I-A-06, I-A-10 and I-A-14) 275
276
For FEM I-A-01, Fig.8. (a) Shows that there is a good correlation between the deformed shape obtained from the 277 FEM and from that of the tests which were carried out by (Choo et. al), also the figure clarifies that yield hinges 278 occur in the chord upper half at the brace-chord intersection while the chord lower half hasn’t been yielded yet. 279
While in FEM I-A-02, in addition to the yielded hinges that occurred in the chord upper half as mentioned above, 280 yield hinges in the chord lower half also occurred which indicates that the chord upper half became stiffer against 281 the local failure that was governing the unstiffened model (I-A-01). At the brace-chord intersection the brace wall is 282 subjected to inelastic bending (clarified in Fig.8. (b)). Fig.9 clarifies that the joint with ID I-A-02 is more ductile 283 than that of the unstiffened joint (I-A-01), and that happened due to yield hinges in the chord lower half. 284
Fig.8. (c) shows that the chord cross section at the brace- chord intersection (stiffened part) and just after the 285 intersection in FEM I-A-06 became fully yielded which indicates that the chord reached its full bending capacity and 286 eliminated the effect of the chord local failure that was governing the unstiffened model (I-A-01). The ovalisation 287 decreased and chord deformed shape is almost circular. It is clear from the curves in Fig.9 that increasing the radial 288 flange diameter increases the joint capacity and decreases the ductility than that of the joint with ID-A-02. 289
While Fig.8 (d) shows that the joint behavior is similar to that of model (ID-02) as shown in Fig.8 (b), the difference 290 between them is that the stresses at chord/brace intersection is relaxed and yielded stresses plateau is extended to a 291 wider zone when compared with that of model (ID-02). Curves in Fig.9 show clearly that increasing the stiffening 292 elements thickness has a great effect on increasing the joint capacity, also it increased the joint ductility due to 293 extending the limit of plastic zone. 294
In FEM I-A-14, Yield hinges that occurred in the chord lower half in model (I-A-02) disappeared (as shown in Fig.8 295 (e)) which indicates decreasing the confinement effect due to increasing the distance between the radial stiffeners, it 296 is shown in Fig.9, that increasing the additional pipe length doesn’t have significant effect on the joint capacity, as it 297 is clear from the curve that the behavior of joint I-A-14 is too close to that of joint I-A-02 but with less ductility. 298
299
300
301
0100200300400500600700800900
1000
0 5 10 15 20
LOAD
(KN
)
OVALISATION (mm)
I-A
I-A-01
I-A-02
I-A-06
I-A-10
I-A-14
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b. THE FAILURE MODE AND DEFORMED SHAPE FOR GROUP I-B 302
303 Fig. 10 The behavior of group I-B 304
305 Fig. 11 Load-ovalisation curves for FEM (I-B-01, I-B-02, I-B-06, I-B-10 and I-B-14) 306
307
As for FEM I-B-01, it is clear that there is a good correlation between the deformed shape obtained from the FEM 308 and from that of the tests which were carried out by (Choo et. al) as shown in Fig.10 (a) also yield hinges occur in 309 the chord upper half at the brace-chord intersection. 310
0
100
200
300
400
500
600
700
0 5 10 15 20
LOAD
(KN
)
OVALISATION (mm)
I-B
I-B-01
I-B-02
I-B-06
I-B-10
I-B-14
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Fig. 10 (b) shows that in FEM I-B-02 at the brace-chord intersection the brace wall is subjected to inelastic bending 311 due to increasing the chord stiffness comparing to that of the brace at the chord-brace intersection. Fig.11 clarifies 312 that the joint with ID I-B-02 is more ductile than that of the unstiffened joint (I-B-01), also the joint capacity 313 increased. 314
While in FEM I-B-06, the brace section is governing the joint capacity as it is fully yielded, also the chord deformed 315 shape is almost circular as shown in Fig. 10 (c). As a result of that, the load-ovalisation curve of FEM I-B-06 shows 316 that the ovalisation value is very small, also it shows that the failure is almost brittle as the brace compressive failure 317 was the governing mode. 318
It is clear from Fig. 10 (d). that the inelastic bending of the brace wall at the brace-chord intersection in FEM I-B-10 319 is more than that in model I-B-02 due to increasing the stiffness of the chord compared to that in FEM I-B-02, but 320 the joint capacity isn’t governed by the brace capacity only. And that is clear from the curves in Fig.11 that the 321 behavior of FEM I-B-10 is close to that of FEM I-B-02, also it shows that increasing the stiffening elements 322 thickness has a great effect on increasing the joint capacity, and on increasing the joint ductility due to extending the 323 limit of plastic zone. 324
In FEM I-B-14 (clarified in Fig. 10 (e)), the yielded zone that occurred in the brace wall at the brace-chord 325 intersection due to the inelastic bending is less that than in FEM I-B-02 which indicates decreasing the confinement 326 effect due to increasing the distance between the radial stiffeners. The curve of FEM I-B-14 in Fig.11, indicates that 327 increasing the additional pipe length doesn’t have significant effect on the joint capacity. 328
329
c. THE DEFORMED SHAPE AND FAILURE MODE FOR GROUP I-C 330
331 Fig. 12 The behavior of group I-C 332
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333 Fig. 13 Load-ovalisation curves for FEM (I-C-01, I-C-02, I-C-06, I-C-10 and I-C-14) 334
In this group (db/d0: brace diameter-to-chord diameter ratio= 0.49) which is close to that of group I-A where (db/d0 = 335 0.54), thus the behavior of these two groups are similar. 336
In FEM I-C-01, Yield hinges occur in the chord upper half at the brace-chord intersection (as shown in Fig.12 (a)). 337
Fig.12 (b) shows that yield hinges in the chord lower half occurred in FEM I-C-02 which indicates that the chord 338 upper half became stiffer against the local failure that was governing model (I-C-01). Thus, the FEM I-C-02 339 becomes more ductile than FEM I-C-01 and that is seen clearly on the curves in in Fig.13 340
While in FEM I-C-06, The chord cross section at the brace- chord intersection (stiffened part) and just after the 341 intersection the chord is fully yielded which indicates that the chord reached its full bending capacity and eliminated 342 the effect of the chord local failure that was governing model (I-C-01), also the ovalisation decreased and chord 343 deformed shape is almost circular and that was clarified in Fig.12 (c). Also Fig.13 (I-C-06) shows that increasing the 344 radial flange diameter has clear effect on decreasing the joint ovalisation and ductility. 345
As for FEM I-C-10, the chord yielded zone increased and the chord cross section at the brace- chord intersection 346 (stiffened part) and just after the intersection became fully yielded which indicates that the chord reached its full 347 bending capacity and eliminated the effect of the chord local failure. At the brace-chord intersection the brace wall 348 is subjected to inelastic bending due to increasing the chord stiffness comparing to that of the brace at the chord-349 brace intersection as shown in Fig.12 (d). The curves in Fig.13 (I-C-10 ) show clearly that increasing the stiffening 350 elements thickness has a great effect on increasing the joint capacity, also it increases the joint ductility and extends 351 the limit of plastic zone until the chord cross section was fully yielded which was the governing failure mechanism. 352
In FEM I-C-14, the Yield hinges zone that occurred in the chord lower half (as per Fig.12 (e)) is less than that 353 occurred in FEM I-C-02 which indicates decreasing the confinement effect due to increasing the distance between 354 the radial stiffeners. It is shown in Fig.13 that increasing the additional pipe length doesn’t have significant effect on 355 the joint capacity, as it is clear from the curve that the behavior of joint I-C-14 is too close to that of joint I-C-02, but 356 with less ductility. 357
358
359
360
361
050
100150200250300350400450500
0 2 4 6 8 10 12 14
LOAD
(KN
)
OVALISATION (mm)
I-C
I-C-01
I-C-02
I-C-06
I-C-10
I-C-14
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d. THE DEFORMED SHAPE AND FAILURE MODE FOR GROUP I-D 362
363 Fig. 14 The behavior of group I-D 364
365 Fig. 15 Load-ovalisation curves for FEM (I-D-01, I-D-02, I-D-06, I-D-10 and I-D-14) 366
In FEM I-D-01, (db/d0: brace diameter-to-chord diameter ratio= 0.74 which is greater than the ratios of groups I-A 367 and I-C), yield hinges occur in the upper and lower halves of the chord at the brace-chord intersection (as shown in 368 Fig.14. (a) ) which indicates that the chord local failure doesn’t have a significant effect on the joint capacity as (I-369 A-01, I-B-01, and I-C-01). 370
0
100
200
300
400
500
600
0 2 4 6 8 10 12
LOAD
(KN
)
OVALISATION (mm)
I-D
I-D-01
I-D-02
I-D-06
I-D-10
I-D-14
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As for FEM (I-D-02), the chord cross section at the brace- chord intersection (stiffened part) and just after the 371 intersection is fully yielded (clarified in Fig.14 (b)) which indicates that the chord reached its full bending capacity 372 and eliminated the effect of the chord local failure that was governing model (I-D-01). Fig.15 shows that FEM I-D-373 02 isn’t more ductile than the unstiffened joint I-D-01 unlike the behavior in groups I-A, I-B and I-C. This is 374 because the joint capacity in FEM I-D-02 was governed by the chord bending capacity and not by the chord local 375 failure as in groups I-A, I-B and I-C. 376
While in FEM I-D-06 and I-D-10, the joint capacity is almost governed by the chord bending capacity, the 377 ovalisation decreased significantly and chord deformed shape is almost circular as shown in Fig.14 (c, d). Which is 378 clarified in Fig.15 as it shows that the ovalisation value is small at the peak load for FEM I-D-06 and I-D-10 379
Fig.14 (e) shows the chord yielded zone hinges that occurred in the chord upper half and lower half in model (I-D-380 14) decreased and the ovalisation is occurred which indicates decreasing the confinement effect due to increasing 381 the distance between the radial stiffeners. In Fig.15, it is seen that FEM I-D-14 is stiffer than FEM I-D-02, because 382 increasing the additional pipe length increases the chord bending capacity at the section that yielded in FEM I-D-02. 383 In other words, the increasing of the length of the additional pipe is acting as a strengthening for the yielded parts of 384 FEM I-D-02 which enhanced the capacity and the ductility as well. 385
386
e. THE DEFORMED SHAPE AND FAILURE MODE FOR GROUP II-A 387
388 Fig. 16 The behavior of group II-A 389
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390 Fig. 17 Load-ovalisation curves for FEM (II-A-01, II-A-02, II-A-06, II-A-10 and II-A-14) 391
As for model (II-A-01), Fig.16 (a) shows that there is a good convergence between the deformed shapes of the test 392 carried out by Choo et.al and the deformed shape obtained from the FEM. As in both (test and the FEM) two 393 significant buckles appears in the chord both sides accompanied with clear ovalisation in the chord upper half. These 394 two buckles decreased after stiffening the joints (as per model II-A-02) and the chord became fully yielded as shown 395 in Fig.16 (b). While these two buckles disappeared after stiffening the joints (as per model II-A-06 and II-A-10) and 396 the chord became fully yielded as shown in Fig.16 (c, d). The behavior of model II-A-14 is clear in Fig.16 (e) which 397 shows that the deformed shape is almost as that of model II-A-02 but chord cross section is fully yielded and the 398 yielded zone extended more than that in model II-A-02. 399
Fig.17 shows that all the joints plotted in the curve is governed by the ovalistion limit except the joint with ID II-A-400 06 and II-A-10. Thus, it is clear that increasing the stiffening elements thickness has effect on decreasing the joint 401 ductility but not as the significant effect of increasing the radial flange diameter. Also it is seen in the curves that 402 FEM II-A-02 and II-A-14 are ductile joints, but the capacity and the ductility of II-A-14 is larger than that of II-A-403 02 because increasing the additional pipe length increased the plastic zone limit. 404
f. THE DEFORMED SHAPE AND FAILURE MODE FOR GROUP II-B 405
406
Fig. 18 The behavior of group II-B 407
0
200
400
600
800
1000
1200
0 20 40 60 80 100
LOAD
(KN
)
OVALISATION (mm)
II-A
II-A-01
II-A-02
II-A-06
II-A-10
II-A-14
0.06 do
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408 Fig. 19 Load-ovalisation curves for FEM (II-B-01 and II-B-02) 409
The deformed shape of model (II-B-01) is similar to that provided by Choo et.al as clear in Fig.18 (a) the chord is 410 subjected to significant ovalisation in the chord upper half accompanied with severe chord plastification. Stiffening 411 that joint with the proposed technique following the geometry of model (I-B-02) leads to brace tensile yielding 412 which means joint full capacity occurred as shown in Fig.18 (b). In Fig.19, it is seen that the failure mode of FEM 413 II-B-02 is a ductile failure as this joint is governed by brace tensile yielding as mentioned. Also it shows that by 414 applying the proposed technique to FEM II-B-01, the joint capacity of II-B-02 almost reached the peak load of joint 415 II-CB-01 that occurred at large value of ovalisation which shows the stiffening efficiency 416
417
g. THE DEFORMED SHAPE AND FAILURE MODE FOR GROUP II-C 418
Fig. 20 The behavior of group II-C 419
0
100
200
300
400
500
600
700
0 10 20 30 40 50 60
LOAD
(KN
)
OVALISATION (mm)
II-B
II-B-01
II-B-02
0.06 do
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420 Fig. 21 Load-ovalisation curves for FEM (II-C-01 and II-C-02) 421
Significant ovalisation in the chord upper half appeared in model II-C-01 accompanied with severe chord 422 plastification which is clarified in Fig.20 (a) after adding the stiffening components to the joint following the 423 geometries of model II-C-02 the chord became fully yielded among the total cross section as shown in Fig.20 (b) 424 which means reaching the joint full capacity. Fig.21 clarifies that the FEM II-C-02 is governed by the peak load and 425 not the deformation limit that was governing II-C-01. Also it shows that by applying the proposed technique to FEM 426 II-C-01, the joint capacity of II-C-02 almost reached the peak load of joint II-C-01 that occurred at large value of 427 ovalisation which shows the stiffening efficiency. 428
h. THE DEFORMED SHAPE AND FAILURE MODE FOR GROUP II-D 429
430
Fig. 22 The behavior of group II-D 431
0
100
200
300
400
500
600
0 10 20 30 40 50 60
LOAD
(KN
)
OVALISATION (mm)
II-C
II-C-01
II-C-02
0.06 do
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432 Fig. 23 Load-ovalisation curves for FEM (II-D-01 and II-D-02) 433
In FEM (II-D-01) the chord is fully yielded without adding additional stiffeners (as shown in Fig.22 (a)) which 434 means that the joint was able to reach the maximum capacity and that is why the gain in group (II-D) was limited 435 when compared to the joints of the other groups of category II. Fig.23 clarifies that the FEM II-D-02 is governed by 436 the peak load and not the deformation limit that was governing II-D-01. Also it shows that by applying the proposed 437 technique to FEM II-D-01, the joint capacity of II-D-02 almost reached the peak load of joint II-D-01 that occurred 438 at large value of ovalisation which shows the stiffening efficiency. 439
440
6. PARAMETERS EFFECT AND DISCUSSIONS 441 442
a. THE RADIAL FLANGE DIAMETER-TO- CHORD DIAMETER RATIO 443 (ds /dO) EFFECT 444
Fig.24. shows that the CHS T-joint compressive capacity increases with the increasing of the radial flange diameter, 445 and also it shows that for the same value of (ds/do) the gain is much bigger with smaller value of β. For example for 446 group I-B (which has smallest β= 0.28), the gain reached 254.7% at (ds/do) equals to 1.4. While as for group I-D 447 (which has largest value of β =0.74), the gain reached 62.1% also at (ds/do) equals to 1.4. This shows that (ds/do) is 448 more efficient with smaller value of β. 449
For group I-B the (ds/do) enhanced the joint capacity until the brace reached its axial capacity. For group I-C, I-D, the 450 gaining was in progress until reached the plastic moment of the chord, as such the joint achieved the maximum gain. 451
0
100
200
300
400
500
600
0 5 10 15 20 25 30
LOAD
(KN
)
OVALISATION (mm)
II-D
II-D-01
II-D-02
0.06 do
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452 Fig.24. Effect of (ds/do) on the gain in joint capacity of category I 453
In case of tension loading, the effect of (ds/do) is presented by Fig.25. Which shows that in groups I-A, II-A, the 454 improvement happened to the CHS T-joints with tensile brace is lesser than that with compressive brace. The 455 stiffening enhanced the T-joint in group II-B until the brace reached its axial capacity, but as for groups II-A, II-C 456 and II-D the gain was increasing until the chord reached its plastic moment. 457
458 Fig.25. Effect of (ds/do) on the gain in joint capacity of category II 459
460
b. THE STIFFENING ELEMENTS THICKNESS TO THE CHORD 461 THICKNESS RATIO (ts /tO) EFFECT 462
The capacity of CHS T-joints either with compressive or tensile brace is directly proportional to (ts/to) values, but the 463 gain in joints subjected to compression is larger than that subjected to tension as shown in Fig.26 and Fig.27. 464
T-joints subjected to compression load with β equals to 0.28, the gain reached 195.1%. While for β equals 0.74, the 465 joint capacity is increased by 62.1% which is also valuable gain. 466
For groups I-D, II-C, II-D, the joint was able to sustain load that leads to the chord plastic moment. While in group II-467 B, the capacity increased until reaching brace axial strength. 468
90.6%
125.0%155.7%
175.0% 184.2%126.7%
186.0%
238.0%254.7% 254.7%
97.2%
127.4%
151.0%
154.8% 155.1%
56.2% 60.1%
62.1% 62.1%62.1%
30.0%
80.0%
130.0%
180.0%
230.0%
280.0%
330.0%
380.0%
1.00 1.10 1.20 1.30 1.40 1.50 1.60
Gai
n %
ds/do
ds/do effect
I-A I-B I-C I-D
42.5%
45.8%47.9%
54.1%54.1%
45.4%
49.5%49.8%
49.8% 49.8%
40.7% 41.2% 41.2% 41.2% 41.2%
5.5% 5.5% 5.5% 5.5% 5.5%
0.0%
10.0%
20.0%
30.0%
40.0%
50.0%
60.0%
1.00 1.10 1.20 1.30 1.40 1.50 1.60
Gai
n %
ds/do
ds/do effect
II-A II-B II-C II-D
FOR I-A β= 0.54, I-B β= 0.28, I-C β= 0.49, I-D β= 0.74
FOR II-A β= 0.54, II-B β= 0.28, II-C β= 0.49, II-D β= 0.74
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469 Fig.26. Effect of (ts/to) on the gain in joint capacity of category I 470
471 Fig.27. Effect of (ts/to) on the gain in joint capacity of category II 472
473
c. The ADDITIONAL PIPE LENGTH TO THE BRACE DIAMETER RATIO 474 (ls /db) EFFECT 475
It is obvious in Fig.28 that for the T-joints with compressive brace, the effect of (ls/db) at smaller values of β is much 476 efficient than that at bigger values of β; as the gain when β= 0.28 reached 127%, while at β= 0.74 the maximum gain 477 is 70.1% 478
For group I-B, the gain decreases with the increasing of (ls) as the confinement caused by the strengthening 479 elements is decreased due to increasing the distance between the radial hollow flanges. 480
Fig.29 shows that the proposed strengthening technique enhanced joint capacity, and it also increased the plastic 481 moment of the chord which is clearly shown for groups II-C, II-D, but as for group II-B the brace reached the 482 ultimate axial load after at (ls/db) equals to 1.5. 483
67.3%90.6%
110.9%127.2% 142.0%
96.4%
126.7%152.8%
175.8%195.1%
73.2%
97.2%
118.8%
135.2% 144.9%
46.7%56.2% 61.1% 62.1%
62.1%
0.0%
50.0%
100.0%
150.0%
200.0%
250.0%
0.50 0.70 0.90 1.10 1.30 1.50 1.70 1.90
Gai
n %
ts/to
ts/to effect
I-A I-B I-C I-D
36.6%
42.5%51.3%
56.8%56.8%
35.7%
45.4% 48.7%48.7% 48.9%
39.8%
40.7% 42.5%42.5% 42.5%
5.5% 5.5% 5.5% 5.5% 5.5%
0.0%
10.0%
20.0%
30.0%
40.0%
50.0%
60.0%
0.50 0.70 0.90 1.10 1.30 1.50 1.70 1.90
Gai
n %
ts/to
ts/to effect
II-A II-B II-C II-D
FOR I-A β= 0.54, I-B β= 0.28, I-C β= 0.49, I-D β= 0.74
FOR II-A β= 0.54, II-B β= 0.28, II-C β= 0.49, II-D β= 0.74
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484 Fig.28. Effect of (ls/db) on the gain in joint capacity of category I 485
486 Fig.29. Effect of (ls/db) on the gain in joint capacity of category II 487
7. PARAMETRIC EQUATION AND ITS ASSESSMENT 488
Based on the parametric study (of category I) shown in table 5, a parametric equation has been concluded to 489 calculate the static capacity of CHS T- joints strengthened by the proposed technique. 490
It is essential to note that some models in category I, the CHS T-joint reached its capacity due to global failure in the 491 connection members -chord reached the plastic moment or brace reached the axial capacity-. These models have 492 been excluded from the regression analysis. Also it is clear in table 5 that as (ls /db) increases than (2) the 493 strengthening technique efficiency decreases; thus the models with (ls /db) ≥ 2 have been excluded from the 494 regression analysis. So it is recommended to use (ls /db) from 1.1 2 which almost have the same effect as shown 495 in table 5 and in Fig.28. 496
𝑃𝑃𝑃𝑃 = 𝑃𝑃 × 𝛼𝛼 Eq. 2 497
The magnification factor (α) in (Eq. 2) is determined by parameters (ds /d), (ts /tO) and (β) using equation (Eq. 3). 498
𝛼𝛼 = 1.2 �𝑠𝑠𝑠𝑠𝑠𝑠𝑜𝑜�1.5
. �𝑠𝑠𝑠𝑠𝑠𝑠𝑜𝑜�0.45
. � 𝑙𝑙𝑠𝑠𝑠𝑠𝑑𝑑�0
. (𝛽𝛽)−0.35 Eq. 3 499
90.6% 91.6% 92.9%97.1%
94.2%
126.7% 127.0%
116.8%111.4% 108.9%
97.2% 94.9% 94.9%99.4% 99.4%
56.2%60.7%
67.4% 70.1% 70.1%
50.0%
60.0%
70.0%
80.0%
90.0%
100.0%
110.0%
120.0%
130.0%
140.0%
150.0%
0.80 1.30 1.80 2.30 2.80
Gai
n %
ls/db
ls/db effect
I-A I-B I-C I-D
42.5%45.8%
51.3%
61.0%
65.1%
45.4%48.7%
48.7%48.7%
48.7%
40.7% 46.2%
50.9%
55.9%61.5%
5.5% 9.4%15.5%
21.3%27.9%
0.0%
10.0%
20.0%
30.0%
40.0%
50.0%
60.0%
70.0%
0.50 1.00 1.50 2.00 2.50 3.00 3.50
Gai
n %
ls/db
ls/db effect
II-A II-B II-C II-D
FOR I-A β= 0.54, I-B β= 0.28, I-C β= 0.49, I-D β= 0.74
FOR II-A β= 0.54, II-B β= 0.28, II-C β= 0.49, II-D β= 0.74
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The capacity of the unreinforced CHS T- joints (P) is calculated using the design code (CIDECT –design guide 1) 500 that cover the design of such connection. The equation proposed by CIDECT to calculate the capacity of 501 unreinforced T-joint, is based on the capacity of T-joints subjected to compressive loading. CIDECT mentioned that 502 in- design guide 1 “part 4.2”- which stated that “The resistance is based on the strength under brace compression loading, 503 although this can also be used for brace tensile loading. The ultimate resistance under tensile loading is usually higher than that under 504 compressive loading. However, it is not always possible to take advantage of this additional strength due to larger deformations or premature 505 cracking”. The strength of the stiffened T-joints is calculated by multiplying the capacity of the unstiffened joint 506 proposed by CIDECT times the magnification factor (α). Thus, the regression analysis is performed based on 507 models of category I where the chords are subjected to compressive brace loads. 508
The applicability of (Eq. 3) is valid when the following ranges are satisfied: 509
1.1≤ �𝑠𝑠𝑠𝑠𝑠𝑠𝑜𝑜� ≤ 1.5 0.75 ≤ �𝑠𝑠𝑠𝑠
𝑠𝑠𝑜𝑜� ≤ 1.75 1.1 ≤ � 𝑙𝑙𝑠𝑠
𝑠𝑠𝑑𝑑� ≤ 2 0.28 ≤ (𝛽𝛽) ≤ 0.74 510
The assessment of (Eq. 3) has been carried out by comparing the static capacity of strengthened CHS T- joints 511 obtained from the FEM and with that calculated using (Eq. 2) and (Eq. 3) and that is illustrated in Fig.30. 512
513
514 Fig.30. Comparison between the calculated and the numerical results 515
516
1.2
1.7
2.2
2.7
3.2
3.7
1.2 1.7 2.2 2.7 3.2 3.7
FEM
CAP
ACIT
Y
CALCULATED CAPACITY
0
1
2
3
4
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35
Join
t cap
acity
Model number
Parametric equation assessment
FEM capacity Calculated capacity
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In order to evaluate precisely the parametric equation, the relative error, the average relative error, the relative 517 standard deviation and the average relative standard deviation are obtained and here is the corresponding values: 518
The average relative error = 8.27 % 519
The relative standard deviation = 9.26 % 520
The average relative standard deviation = 9.11 % 521
These values reflect the reliability and the accuracy of the proposed parametric equation to calculate the static 522 capacity of CHS T- joints strengthened by the proposed technique. 523
8. CONCLUSIONS 524
In this study a strengthening technique was proposed for CHS T- joints either subjected to tension or compression 525 load cases. Finite element modeling were performed after calibration with independent experimental results. Based 526 on the results obtained from 104 models of CHS T-joints strengthened with the proposed technique, the following 527 conclusions are drawn: 528
a. By using the proposed strengthening technique, the joint capacity enhanced significantly as in some cases 529 the brace axial capacity or chord plastic moment was reached; which means maximum gain has been 530 occurred for those cases. 531
b. (ds/do) is more effective in the proposed strengthening technique at smaller values of chord diameter to brace 532 diameter ratio (β). 533
c. Increasing (ts/to) is efficient for all values of β and for both brace load cases (tension/compression). 534 d. For CHS T-joints with compressive axial brace, decreasing the distance between the two additional flanges 535
(ls) with relative to the brace diameter (db) leads to high gain values. 536 e. For CHS T-joints with tensile axial brace, the joint capacity is directly proportional to the distance between 537
the two additional flanges with respect to the brace diameter (ls/db). 538 f. (ds/do) is the most effective parameter for CHS T-joints subjected to compressive axial brace. 539 g. (ls/db) is the most effective parameter for CHS T-joints subjected to tensile axial brace. 540 h. The efficiency of the CHS T-joint increased as the difference between the tensile capacity of the joint and 541
that of the compressive joint decreased. 542
543
9. NOTATION 544
The following symbols are used in this paper: 545 do = outer diameter of the chord; 546 to = thickness of the chord; 547 lo = length of the chord; 548 Eo = young’s modulus of the chord; 549 fy,o = yield stress of the chord; 550 db = diameter of the brace; 551 tb = thickness of the brace; 552 lb = length of the brace; 553 Eb = young’s modulus of the brace; 554 fy,b = yield stress of the brace; 555 β = diameter ratio db / do; 556
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2γ = chord diameter to thickness ratio do / to 557 ds = radial flange diameter 558 ts = stiffening elements thickness 559 ls = additional pipe length 560 Ps = calculated strengthened CHS T-joint capacity 561 P= calculated unreinforced CHS T-joint capacity 562 α = magnification factor 563 564
10. RECOMMENDATION FOR FUTURE RESEARCH 565
Further studies can be carried out by changing the weld between the steel elements from full penetration (as 566 followed in this study) into fillet weld. For such study, it is recommended to follow the suggestion provided by (Kim 567 et al. 2015) for the improved modelling technique including fillet welding. 568
11. REFERENCES 569 - ANSYS program. Release 14 user’s manual, Swanson analysis system. 570 - Choo, Y.S., Liang, J. X., and van der Vegte, G. J. 2004. An effective external reinforcement scheme for 571
circular hollow section joints. Proceedings of ECCS-AISC Workshop Connections in Steel Structures V, 572 Bouwen met Staal, Zoetermeer, pp. 423–432. 573
- Choo, Y.S., van der Vegte, G. J, Zettlemoyer, N., LI, B.H., and Liew, J.Y.R. 2005. Static Strength of T-Joints 574 Reinforced with Doubler or Collar Plates. Journal of Structural Engineering. (131):119-138. doi: 575 10.1061/(ASCE)0733-9445(2005)131:6(119). 576
- CIDECT. 2008. Design guide for circular hollow section (CHS) joints under predominantly static loading. 577 - Kim, WB., Shin, KJ., Lee, HD. et al. 2015. Strength Equation of Longitudinal Plate-to-Circular Hollow Section 578
(CHS) Joints. International Journal of Steel Structures. 15(2): 499-505 579 - Lu, L.H., de Winkel, G.D., Yu, Y., and Wardenier, J. 1994. Deformation limit for the ultimate strength of 580
hollow section joints. Proceeding 6th International Symposium on Tubular Structures, Australia, The 581 Netherlands, pp. 341-347. 582
- Lee, M.M.K., and Llewelyn-Parry, A. 2004. Offshore tubular T-joints reinforced with internal plain annular 583 ring stiffeners. Journal of Structural Engineering ASCE. 130(6): 942–951. doi: 10.1061/(ASCE)0733-584 9445(2004)130:6(942). 585
- Lesani, M., Bahaari, M.R., and Shokrieh, M.M. 2013. Numerical investigation of FRP strengthened tubular T-586 joints under axial compressive loads. Composite Structures. (100): 71-78. 587
- Mohamed, M.A., Shaat, A.A., and Sayed-Ahmed, E.Y. 2013. Finite element modeling of CHS T-Joints 588 Strengthened using Through-bolts. The 5th International Conference on Structural Engineering, Mechanics 589 and Computation. September 2- 4, Cape Town, South Africa, pp.1335-1340. doi: 10.1201/b15963-240. 590
- Nassiraei, H., Lotfollahi-Yaghin, M.A., and Ahmadi, H. 2016. Static strength of collar plate reinforced tubular 591 T/Y-joints under brace compressive loading. Journal of Constructional Steel Research. (119): 39-49. 592
- Shao, Y., Lie, S., and Chiew, S. (2010). Static strength of tubular T-joints with reinforced chord under axial 593 compression. Advances in Structural Engineering. (13): 369-377. 594
- Shubin, H., Yongbo, S., and Hongyan, Z. 2013. Static Strength of Circular Tubular T-joints with Inner 595 Doubler Plate Reinforcement Subjected to Axial Compression. The Open Ocean Engineering Journal. (6): 1-596 7. 597
- Zhu, L., Zhao, Y., Li, S., Huang, Y., and Ban, L. 2014. Numerical analysis of the axial strength of CHS T-598 joints reinforced with external stiffeners. Thin-Walled Structures. (85): 481-488. 599
- Zhu, L., Han, S., Song, Q., Ma, L., Wei, Y., and Li, S. 2016. Experimental study of the axial compressive 600 strength of CHS T-joints reinforced with external stiffening rings. Thin-Walled Structures. (98): 245-251. 601
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